The world’s most advanced ELEKTA 306-conductor magnetoencephalography, PERFEXION gamma knife and other highly sophisticated technical equipment, as well as GE3.0 magnetic resonance, BIOLOGICAL long-range video EEG, PETCT, Zeiss and Leica microscopes and other advanced equipment, to provide a guarantee for the success of the surgery. Magnetoencephalography is an important non-invasive test in clinical epileptology. Magnetoencephalography is more sensitive than electroencephalography in detecting cortical epilepsy. In temporal lobe epilepsy, magnetoencephalography is able to clearly localize temporal lobe epileptogenic foci and to differentiate between medial, lateral, and diffuse painful seizures. In non-temporal lobe epilepsy, magnetoencephalography can provide unique information in cases where no foci are found and can help determine the relationship of seizure activity to the epileptogenic foci and the speech cortex. Magnetoencephalography can also provide assistance in the clinical diagnosis of cortical aphasia, Launder-kleffner syndrome, and post-surgical recurrence of epilepsy. Reevaluation of MRI guided by magnetoencephalography can help to detect hidden epileptogenic foci. Magnetoencephalography is also superior to EEG in the preoperative evaluation of epilepsy, and complete resection of epileptogenic foci identified by magnetoencephalography can predict the degree of postoperative epileptic seizure control. Magnetoencephalography also has many important features such as the ability to accurately localize the sensorimotor and speech center cortices. Magnetoencephalography (MEG magneteoncephalophy) is a technique that detects weak magnetic fields in the brain by means of a highly sensitive detection instrument, the superconducting quantum statistical inferometer (SOUIDS). Although both electroencephalography (EEG) and MEG are neurophysiologically based techniques that record synchronized synaptic potentials in cortical pyramidal cells, MEG has several theoretical advantages over EEG: (1) the magnetic field is less distorted when blocked by the scalp and skull, which allows MEG to obtain better spatial resolution This allows MEG to obtain better spatial resolution. (2) Since EEG is sensitive to both tangential and radial components of current – electrical activity in the sulcus and electrical activity in the top and bottom of the gyrus – MEG detects only the tangential component, i.e., selectively detects electrical activity in the sulcus. generated by intracellular currents. (4) The raw data of MEG are composed of traces, which represent the measured magnetic field intensity recorded at different loci. We are able to reduce these data into three-dimensional images to localize, orient and time the underlying neuronal activity in the brain; we are also able to overlay these data with magnetic resonance images to form magnetic data images (MSI). (5) Magnetoencephalography is a completely non-invasive test that greatly reduces the need for invasive tests such as cortical electrode recordings. The magnetoencephalography clearly shows the epileptic lesion, and the magnetoencephalography clearly shows the lesion in the posterior part of the lesion. A GE3.0 MRI can help identify subtle intracranial lesions such as gray matter translocation and small tumors that cause epilepsy. The PERFEXION Gamma Knife can be used to treat functional epilepsy, refractory epilepsy, and postoperative residual epilepsy.